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2 nd Year Practicals November 2008

2 nd Year Practicals November 2008. Dr Jonathan Stirk JAS@psychology.nottingham.ac.uk Room C44 Office Hours: Wednesdays 10-11am Demonstrator: Maria Ktori Contact by e-mail: lpxmk2@nottingham.ac.uk Room: A24 Office hour: Mondays 2pm.

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2 nd Year Practicals November 2008

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  1. 2nd Year PracticalsNovember 2008 Dr Jonathan Stirk JAS@psychology.nottingham.ac.uk Room C44 Office Hours: Wednesdays 10-11am Demonstrator: Maria Ktori Contact by e-mail: lpxmk2@nottingham.ac.uk Room: A24 Office hour: Mondays 2pm

  2. Selective Attention & the Flanker Compatibility Effect (FCE) • Structure of practical • 5 week structure

  3. Aims of this practical • To learn about the flanker compatibility effect • To design an experiment to test a specific hypothesis about flanker effects • To learn to implement a design using E-Prime software • To learn to collect and analyze data using computer software (E-Prime, SPSS)

  4. What is attention? • ‘Attention is the process of concentrating on specific features of the environment, or on certain thoughts or activities. This focusing on specific features of the environment usually leads to the exclusion of other features of the environment ‘. • Colman (2001)

  5. What is selective attention? • 2 main types of attentional tasks • Divided attention tasks (dual tasks) • Paying attention equally to more than one thing • E.g. Reading out loud a story , whilst writing down dictated words (Spelke, Hurst & Neisser, 1976), driving whilst listening for a specific news item on the radio. • Selective attention tasks • Paying attention to one source of information whilst ignoring everything else • E.g. Identifying words presented to the left ear, whilst ignoring words presented to the right ear in a dichotic listening task (Cherry, 1953)

  6. Models of selective attention • Where within the flow of information does specific information become selected and other information dismissed? i.e. When does selection take place? • Does selection occur early in processing or later on? Sensory Store Response Further processing STIMULI Sensory Store Response Further processing STIMULI

  7. Early versus late models of selective attention • Early-selection models assume that selection occurs early-on in processing [after analysis of physical characteristics/features e.g. Broadbent (1958)]. From this point on unattended information receives little or no further processing. • So NO semantic (identification) processing of the ignored/unattended information.

  8. Early versus late models of selective attention • Late-selection models propose that ALL stimuli are analysed up to the point of identification (to a semantic level) and selection occurs after this point, i.e. later on in the processing stream. • So to-be-ignored stimuli receive considerable processing and selection occurs much closer to the response end.

  9. Early and late selection All messages in Physical characteristics Meaning Selected message Selected message

  10. BIG questions! • Some questions in attentional research are: • “To what extent are irrelevant stimuli processed in selective visual attention tasks?” • “How can we explain what is and isn’t selected?”

  11. How can we examine the extent to which irrelevant information is processed? • Priming studies • Do to-be-ignored stimuli prime future performance on a cognitive task? • Flanker tasks • Do surrounding irrelevant stimuli affect performance on target stimuli? • Eriksen & Eriksen (1974): classic flanker effect • A response competition paradigm (similar to Stroop!) • This is a selective visual attention task • It can also be used to examine ‘automatic’ processing of stimuli (processing without attention) • Or… Capture of attention by irrelevant stimuli

  12. Eriksen & Hoffman (1973) • Original exp’t used circular displays of letters and S’s had to identify the presence of a target (out of 4 possible targets) flanked by distracters H U M H U A A M M U U H

  13. The flanker compatibility effect • Flankers are stimuli which are presented spatially close to target stimuli and which should be ignored • Despite the irrelevance of flankers to the target task they are often shown to interfere with target responses • The original task involved being presented with 5 letter strings and determining the identity of the middle letter by moving a lever to the left or right • More modern versions involve left and right hands pressing specific buttons/keys to identify a target

  14. Eriksen et al (1974): linear display task LEFT HAND RESPONSE RIGHT HAND RESPONSE REVERSE MAPPINGS CAN BE USED TOO! Target: H K S C flankers flankers H H K H H E.g. Respond left S S C S S E.g. Respond right target

  15. Compatibility of responses • However, the compatibility of the target and flanker responses is important • RT to target: Incompatible trials > Compatible trials

  16. Defining the flanker compatibility effect • The FCE is the difference in RT between the two types of compatibility trials • FCE = Incompatible trials – compatible trials • E.g. 500 ms-420 ms FCE of 80ms • Sometimes the effect is measured with respect to a base-line condition • One in which flankers are Neutral with respect to target responses • E.g XXSXX (where the X flanker does not belong to the target set) • RT differences can then be framed as “costs” or “benefits” • i.e. we can examine facilitation and interference

  17. What factors moderate the FCE? • Research has shown that the FCE is quite robust • However, a number of factors have been shown to moderate the effect • Early research suggested that flanker-target distance was important • Eriksen & Eriksen (1974) showed that larger spatial separation (eccentricity) reduced the FCE • Distracters within 1° of visual angle could not be ignored • Possible evidence for a ‘fixed-width spotlight’ of selective attention (Posner, 1980)

  18. < 1 deg S C S Fixed-width spotlight metaphor Flankers cannot be ignored as they are within the space selected for attention Fixed width (2 deg)

  19. Fixed-width spotlight metaphor Flankers may now receive less processing > 1 deg S C S Fixed width (2 deg)

  20. Explanations of separation effects • The spotlight metaphor helps to explain the effects of target-flanker separation on the FCE. • However, other explanations are viable • Visual acuity decreases the further objects are from the point of fixation • So perhaps increasing the size of flankers/targets is important in controlling for acuity problems • Distance is confounded by Gestalt grouping • The law of proximity suggests that closeness effects grouping of stimuli

  21. Law of proximity Grouped by column Grouped by row

  22. So does perceptual grouping affect the FCE? • What if attention is to objects rather than space? • If attention is object-based then principles of grouping may affect what is selected for further processing • Driver & Baylis (1989) used ‘common motion’ to compete the ‘distance’ vs ‘grouping’ hypotheses

  23. H X H Driver & Baylis (1989) • The results showed that moving distant distracters (e.g. the H’s above) produced more interference than the static closer distracters (e.g. the T’s above). • So, perceptual grouping seems important in the allocation of attention and in the FCE T T

  24. Further effects of grouping • Harms & Bundesen (1983) • Used colour segregation of targets/distracters • E.g. (1) F T F versus (2) F T F • This encouraged colour segregation of targets/distracters in condition 2 • Smaller flanker compatibility effects in condition 2

  25. Further factors moderating FCE • Miller (1991) manipulated five factors to try and eliminate the FCE and determine any boundary conditions • Poor spatial resolution • Inability to hold attentional focus on a fixed location • Inability to focus completely on an empty display location • Inability to filter out stimuli which onset at the same time as the target during the task • Inability to prevent analysis of all stimuli when there is insufficient demand by the attended items

  26. Consistent & varied mapping • Miller hypothesised that we are unable to maintain attention on a fixed location and this may be why attention leaks to the irrelevant distracters • In the linear task the target is always in the same spatial location • So, he varied the locations of targets/distracters and used a __ (bar) pre-cue to direct attention to the location • The FCE was NOT diminished when varied mapping was used

  27. +

  28. H X X

  29. Miller’s Boundary Conditions • Perhaps it is not the constancy but rather the emptiness of the attended location which prevents early selection from fully excluding other locations from further processing • Necessary object hypothesis • Miller used an RSVP version of the flanker task to test this

  30. RSVP task 200ms F = flanker T = target 200ms • The necessary object hypothesis predicts an FCE only when the target appears in frame 1 (as there is no previous object in the target location) • However, results showed that the FCE was present in later frames refuting the hypothesis 5 200ms 4 200ms 3 2 1

  31. Miller’s Boundary Conditions • Maybe we can’t filter out flankers because they onset at the same time as the target • Yantis & Jonides (1984) had shown that abrupt onsets attract attention in a visual task • Miller varied onset/offset transients of flankers/targets • Used ‘figure 8’ concept.

  32. Yantis & Jonides’ ‘figure 8’ • Results showed that transients had no effect on the FCE • Transients therefore do not seem to be responsible for the partial leakage of unattended stimuli through an early selection mechanism.

  33. Miller’s Boundary Conditions • What if processing of the irrelevant flankers is because attentional ‘capacity’ is underloaded leaving room for processing of the flankers? • Perceptual underload hypothesis • So Miller varied the amount of relevant information and examined the FCE

  34. TARGET (attended)REGION Number of letters varied Perceptual Underload Stimuli Flankers

  35. Perceptual Underload Stimuli • Results showed that the FCE was eliminated for the larger set sizes • Finally a boundary condition for FCE? • NO as there was a confound of timing • Further experiments did NOT support the underload hypothesis

  36. So what are you going to do? • Get into small groups (3) and design an experiment to investigate a factor which may effect the FCE • Design needs to be at least a 2 x 2 factorial design • E.g. 2 IV’s! • 1. Compatibility of flankers (compatible vs. incompatible) • 2. Other variable of your own!

  37. Examples of factors to manipulate • Any grouping factor e.g. Colour segregation • Harms & Bundesen (1983) • Number of flankers? • Nature of flankers? • Pictures vs. words? • Target-flanker separation • E.t.c.

  38. So for example… manipulate distanceS,C left H,K right (response pairings) Leads to 4 conditions (cells) in the design, tested within-subjects

  39. How are you going to do this? • Using E-Prime to control stimulus display • Create stimuli materials in E-Prime or maybe using Paint or other graphics program (PowerPoint plus Paint) • DEMO OF TEMPLATE (using letter stimuli and manipulating target-flanker DISTANCE)

  40. Samples need to be weighted to balance out compatible/incompatible trials So minimum number of trials is 32

  41. What to do - recap • So choose a further IV that you can manipulate at 2 levels • E.g. you may manipulate a grouping factor at 2 levels • You might look at what type of information (e.g. semantic?) can influence target response • Create stimuli for your experiment • Program E-Prime • Run design

  42. Types of flanker tasks you can use • Classic Letter flanker task S C S • Colour flanker task * * * (Left- red/white, Right- Blue,green) respond to target colour • Letter-number task 2 A 2 (classify target as either a letter or a number) • Spatial/Arrows flanker task < < < vs. < > < • Semantic classification flanker task • Classify names as male/female • E.g. John Samantha John (incompat) vs. June Samantha June (compat) • Classify target as large/small etc. • Remember this is essentially a response competition paradigm. If target responses are slowed then it must be because of some flanker processing.

  43. Some References • Bindemann, M., Burton, A., & Jenkins, R. (2005). Capacity limits for face processing. Cognition, 98(2), 177-197. • Diedrichsen, J., Ivry, R.B., Cohen, A. & Danziger, S. (2000). Asymmetries in a unilateral flanker task depend on the direction of the response: The role of attentional shift and perceptual grouping. Journal of Experimental Psychology: Human Perception and Performance, 26, 113-126. • Driver, J. & Baylis, G.C. (1989). Movement and visual attention: the spotlight metaphor breaks down. Journal of Experimental Psychology: Human Perception & Performance, 15(3), 448-456. • Eriksen, B. A., & Eriksen, C. W. (1974). Effects of noise letters upon the identification of a target letter in a nonsearch task. Perception & Psychophysics, 16, 143-149. • Eriksen, C.W. (1995). The flankers task and response competition: a useful tool for investigating a variety of cognitive problems. Visual Cognition, 2, 101-118. (available as a .pdf from me) • Harms, L & Bundesen, C. (1983). Color segregation and selective attention in a nonsearch task. Perception & Psychophysics, 33, 11-19.

  44. Some References • Miller, J. (1991). The flanker compatibility effect as a function of visual angle, attentional focus, visual transients, and perceptual load: a search for boundary conditions. Perception & Psychophysics, 49 (3), 270-288. • Shomstein, S. & Yantis, S. (2002). Object-based attention: sensory modulation or priority setting? Perception & Psychophysics, 64(1), 41-51. • Styles, E. (1997). The psychology of attention. UK: Psychology Press [Chapter 3] • Jenkins, R., Lavie, N. & Driver, J. (2003). Ignoring famous faces: category-specific dilution of distractor interference. Perception and Psychophysics, 65(2), 298-309. • Lachter, J., Forster, K. I., & Ruthruff, E. (2004). Forty-five years after Broadbent (1958): Still no identification without attention. Psychological Review, 111(4), 880-913.

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